Abstract
The internal facies and sequence architecture of a Late Jurassic (Late Kimmeridgian) shallow carbonate ramp was reconstructed after the analysis and correlation of 17 logs located south of Teruel (northeast Spain). The studied rocks are arranged in five high-frequency sequences A–E (5–26 m thick) bounded by discontinuities traceable across the entire study area (20 × 25 km). Facies analysis across these sequences resulted in the reconstruction of three sedimentary models showing the transition from interior ramp environments (i.e., lagoon, backshoal, and shoal) to the progressively deeper foreshoal and offshore areas. Coral-microbial reefs (meter-sized patch and pinnacle reefs) have a variable development throughout the sequences, mostly in the foreshoal and offshore-proximal environments. The preferential occurrence and down-dip gradation of non-skeletal carbonate grains has been evaluated across the three models: low-energy peloidal-dominated, intermittent high-energy oolitic-dominated and high-energy oolitic–oncolitic dominated. The predominance of these non-skeletal grains in the shoal facies was mainly controlled by the hydrodynamic conditions and spatial heterogeneity of terrigenous input. The models illustrate particular cases of down-dip size-decrease of the resedimented grains (ooids, peloids, oncoids) due to storm-induced density flows. Offshore coarsening of certain particles (intraclasts, oncoids) is locally observed in the mid-ramp areas favorable for microbial activity, involving coral-microbial reef and oncoid development. The observed facies variations can be applicable to carbonate platforms including similar non-skeletal components, where outcrop conditions make the recognition of their three-dimensional distribution difficult.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Aurell M, Bádenas B (2004) Facies and depositional sequence evolution controlled by high-frequency sea-level changes in a shallow-water carbonate ramp (Late Kimmeridgian, NE Spain). Geol Mag 141:717–733
Aurell M, Bosence D, Waltham DA (1995) Carbonate ramp depositional systems from a Late Jurassic epeiric platform (Iberian basin, Spain): a combined computer modelling and outcrop analysis. Sedimentology 42:75–94
Aurell M, Bádenas B, Bosence D, Waltham DA (1998) Carbonate production and offshore transport on a Late Jurassic carbonate ramp (Kimmeridgian, Iberian basin, NE Spain): evidence from outcrops and computer modeling. In: Wright VP, Burchette TP (eds) Carbonate ramps. Geol Soc Lond Spec Publ 149, pp 137–161
Aurell M, Robles S, Bádenas B, Quesada S, Rosales I, Meléndez G, García-Ramos JC (2003) Transgressive/regressive cycles and Jurassic palaeogeography of northeast Iberia. Sediment Geol 162:239–271
Aurell M, Bádenas B, Ipas J, Ramajo J (2009) Sedimentary evolution of an Upper Jurassic carbonate ramp (Iberian Basin, NE Spain). In: van Buchem F, Gerdes FK, Esteban M (eds) Reference models of Mesozoic and Cenozoic carbonate systems in Europe and the Middle East—stratigraphy and diagenesis. Geol Soc Lond Spec Publ (in press)
Bádenas B, Aurell M (2001a) Kimmeridgian palaeogeography and basin evolution of northeastern Iberia. Palaeogeogr Palaeoclimatol Palaeoecol 168:291–310
Bádenas B, Aurell M (2001b) Proximal–distal facies relationship and sedimentary processes in a storm dominated carbonate ramp (Kimmeridgian, northwest of the Iberian Ranges, Spain). Sediment Geol 139:319–342
Bádenas B, Aurell M (2003) Análisis comparado y controles en la sedimentación de dos arrecifes de la zona media de una rampa carbonatada del Jurásico Superior de la Cordillera Ibérica. Revista Sociedad Geológica de España 16:151–166
Bádenas B, Aurell M, Gröcke DR (2005) Facies analysis and correlation of high-order sequences in middle-outer ramp successions: variations in exported carbonate in basin-wide δ13Ccarb (Kimmeridgian, NE Spain). Sedimentology 52:1253–1276
Borkhataria R, Aigner T, Pöppelreiter MC, Pipping JCP (2005) Characterisation of epeiric “layer-cake” carbonate reservoirs: Upper Muschelkalk (Middle Triassic), The Netherlands. J Petroleum Geol 28:119–146
Burchette TP, Wright VP (1992) Carbonate ramp depositional systems. Sediment Geol 79:3–57
Colombíé C, Strasser A (2005) Facies, cycles and controls on the evolution of a keep-up carbonate platform (Kimmeridgian, Swiss Jura). Sedimentology 52:1207–1228
Dahanayake K (1977) Classification of oncoids from the Upper Jurassic carbonates of the French Jura. Sediment Geol 18:337–353
Droste H (2006) A new model for epeiric carbonate platforms. GEO 2006 Middle East Conference and Exhibition 27–29 March 2006. Manama, Bahrain
Dupraz C, Strasser A (1999) Microbialites and micro-encrusters in shallow coral bioherms (Middle to Late Oxfordian, Swiss Jura Mountains). Facies 40:101–130
Dupraz C, Strasser A (2002) Nutritional modes in coral-microbialite reefs (Jurassic, Oxfordian, Switzerland): evolution of trophic structure as a response to environmental change. Palaios 17:446–471
Einsele G (1992) Sedimentary basins. Springer, Berlin Heidelberg New York, 627 pp
Fezer R (1988) Die oberjurassische karbonatische Regressionsfazies im südwestlichen Keltiberikum zwischen Griegos und Aras de Alpuente (Prov. Teruel, Cuenca, Valencia, Spanien). Arb Institut fur Geologie und Paläontologie Universitat Stuttgart 84:1–119
Gradstein F, Ogg J, Smith A (2004) A geologic time scale 2004. Cambridge University Press, Cambridge, 589 pp
Hallock P (1988) The role of nutrient availability in bioerosion: consequences to carbonate build-ups. Palaeogeogr Palaeoclimatol Palaeoecol 63:275–291
Hillgärtner H, Strasser A (2003) Quantification of high-frequency sea-level fluctuations in shallow-water carbonates: an example from the Berriasian–Valanginian (French Jura). Palaeogeogr Palaeoclimatol Palaeoecol 200:43–63
Leinfelder RR, Nose M, Schmid D, Werner W (1993) Microbial crusts of the Late Jurassic: composition, palaeoecological significance and importance in reef construction. Facies 29:195–230
Nose M (1995) Vergleichende Faziesanalyse und Palökologie korallenreicher Verflachungsabfolgen des Iberischen Oberjura. Profil 8:1–237
Osleger D (1991) Subtidal carbonate cycles: implications for allocyclic vs autocyclic controls. Geology 19:917–920
Salas R, Casas A (1993) Mesozoic extensional tectonics, stratigraphy and crustal evolution during the Alpine cycle of the eastern Iberian basin. Tectonophysics 228:33–55
Samankassou E, Tresch J, Strasser A (2005) Origin of peloids in Early Cretaceous deposits, Dorset, South England. Facies 51:264–273
Strasser A (1986) Ooids in Purbeck limestones (lowermost Cretaceous) of the Swiss and French Jura. Sedimentology 33:711–727
Strasser A (2007) Astronomical time scale for the Middle Oxfordian to Late Kimmeridgian in the Swiss and French Jura Mountains. Swiss J Geosci 100:407–429
Védrine S, Strasser A, Hug W (2007) Oncoid growth and distribution controlled by sea-level fluctuations and climate (Late Oxfordian, Swiss Jura Mountains). Facies 53:532–535
Wright VP, Burchette T (1996) Shallow-water carbonate environments. In: Reading HG (ed) Sedimentary environments: processes facies and stratigraphy. Blackwell, London, pp 325–394
Acknowledgments
Financial support was provided by the research Spanish government projects CGL2007-62469/BTE, CGL2008-01237/BTE and CGL2008-04916/BTE, and by the Aragón government (Grupo “Reconstrucciones Paleoambientales”). We are grateful to André Strasser and André Freiwald for their constructive comments, which improved the original version of the manuscript.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Bádenas, B., Aurell, M. Facies models of a shallow-water carbonate ramp based on distribution of non-skeletal grains (Kimmeridgian, Spain). Facies 56, 89–110 (2010). https://doi.org/10.1007/s10347-009-0199-z
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10347-009-0199-z